The present study reports a protocol for chromosome screening of human embryos that uses spent culture medium, which avoids embryo biopsy and enables chromosome ploidy identification using NGS. The present article presents the detailed procedure, including the preparation of culture medium, whole genome amplification (WGA), next-generation sequencing (NGS) library preparation, and data analysis.
In clinical in vitro fertilization (IVF), the prevailing method for PGT-A requires biopsy of a few cells from the trophectoderm (TE). This is the lineage that forms the placenta. This method, however, requires specialized skills, is invasive, and suffers from false positives and negatives because the chromosome numbers in the TE and the inner cell mass (ICM), which develops into the fetus, are not always the same. NICS, a technology requiring sequencing of DNA that released into the culture medium from both TE and ICM, may offer a way out to these problems but has previously been shown to have limited efficacy. The present study reports the full protocol of NICS, which includes culture medium sampling methods, whole genome amplification (WGA) and library preparation, and NGS data analysis by analysis software. Considering the different cryopreservation times in different embryo laboratories, embryologists have two methods for collecting embryo culture medium that can be selected according to the actual conditions of the IVF laboratory.
Assisted reproductive technologies (ARTs) have been increasingly used for the treatment of infertility. However, the success rate of ART, such as IVF, has been limited, and the pregnancy loss rate is significantly higher than that of the normal population1. The main cause of these problems is chromosomal abnormalities, which commonly exist in preimplantation human embryos2. PGT-A is an effective method of screening embryos for chromosomal balance before implantation3,4. Some studies have proven that PGT-A can reduce the rate of abortion and improve the rate of pregnancy5,6,7,8. However, PGT-A requires complex technical expertise that requires specific training and experience. The invasive embryo biopsy procedure could also potentially cause damage to the embryos9. Studies have shown that blastomere biopsy can hinder subsequent development, and the number of biopsied TEs may affect the implantation rates10. Although the long-term biosafety issue of embryo biopsy has not yet been evaluated thoroughly in humans, animal studies have shown its negative influences on embryo development11,12,13.
Previous reports indicated that trace amounts of DNA materials were secreted into the culture medium during embryo development, and efforts have been made to perform comprehensive chromosome screening (CCS) using spent embryo culture medium14,15,16,17,18. However, the detection rates and the accuracy of the tests have not met the requirements for extensive clinical use. The present study reported an improvement in the NICS assay for increasing the detection rates as well as the accuracy of the NICS test19. In recent years, blastocoele fluid (BF) has been studied as an analytical sample of minimally invasive PGT-A. However, the proportion of successful genome-wide amplification and detectable DNA in blastocyst fluid samples ranges from 34.8% to 82%20,21,22. The volume of BF reported in various studies ranges from 0.3 nL to 1 µL. In view of the low amount of DNA in BF, it is possible to increase the amount of cell-free DNA by mixing blastocyst fluid and culture medium to improve the success rate and consistency of detection. Kuznyetsov et al.23 and Li et al.24 treated the zona pellucida with a laser and released blastocyst fluid into the culture medium to improve the total amount of embryonic DNA, and the amplification rate of the combined medium/BF samples after WGA was 100% and 97.5%, respectively. Jiao et al.25 also obtained a 100% amplification success rate by using the same method.
The present study reports a detailed protocol that includes spent media sample preparation, NGS preparation and data analysis. By carefully removing cumulus cells from oocytes, the present study performed intracytoplasmic single sperm injection (ICSI) and blastocyst culture. The, day 4-day 5/day 6 spent medium was collected for WGA and NGS library preparation. By using NICS technology, the present study streamlined the WGA and NGS library preparation steps in approximately 3 h and obtained CCS results noninvasively in approximately 9 h.
Ethical permission was acquired from the Ethics Committee of Peking University Third Hospital.
1. Preparation
NOTE: The required materials and equipment are listed in Table of Materials.
2. Protocol 1: Sample collection
3. Protocol 2: Library Construction
The present study applied the proposed method to a patient. IRB approval and informed consent were obtained before the application of NICS analysis. The present study obtained 6 blastocysts from patients and performed NICS on all 6 embryos on day 4 to day 5 medium. Chromosome abnormalities caused by the parents' balanced translocation were detected in five of chromosomes with the NICS assay; therefore, they could not be used for transfer (Figure 4A-E). The NICS results of the two embryos showed the same karyotype 45, and XN and -18 (×1) were both chromosome 18 deletions (Figure 4A, B). The karyotype 46, XN, -1p (pter→p21.1, ×1) is only the short arm of the chromosome 1 pter→p21.1 region deletion (Figure 4D).
The NICS results showed karyotype 46, XN, +1p (pter→p21.2, ×3), and -18(q21.32→qter, ×1), which indicated that both the long arm of chromosome 18 q21.32→qter region deletion and short arm of chromosome 1 pter→p21.2 region were duplicated (Figure 4E). Although karyotypes 46, XN, +5q (×4), and -8 (×1, mos) are chromosome 5 duplications and show 8 mosaic differences, the NICS assay can screen all 24 chromosomes for aneuploidy. This process provides a new method for transferring single normal karyotype blastocysts.
Figure 1. The removal completeness of cumulus cells. (A) The oocytes with cumulus cells. (B) The oocytes without cumulus cells attached. Please click here to view a larger version of this figure.
Figure 2. Cumulus cells are removed from an embryo at D3 before transferring to the BM. All attached cumulus cells must be removed before the medium change from the initial cleavage embryo culture medium plate to the blastocyst culture medium plate, which is on Day3 after the embryos reach 8-cell stage. Any cumulus cells which are not removed will interfere in the final analysis giving false negative results. Please click here to view a larger version of this figure.
Figure 3. Data Analysis. (A) There are different options for the user application. For sequencing platform corporation, users can choose Illumina, Ion Torrent or MGI. The users can choose whether the gender information is reported. Finished the above parameter setting, click on the box under File upload and choose the appropriate sequencing files to upload. For Illumina, choose the files with an extension of fastq.gz. Click Submit to start the analysis after successfully upload. (B) The view of summary table. The summary table consists of following information: Sample Name: The name of each NICS sample is listed; Data QC: Indicates whether the sequencing file passes the QC for NICS analysis; AI Rating: The rating (A, B or C) for each NICS sample; AI_Rating Interpretation: Evaluation of embryo implantation potential; AI Grading: The score for each NICS sample; CNV plot (Whole Genome): View the CNV profiles of all chromosomes; (C) The Save Report Page. Click Export report button next to the Summary of Results. Select the information you want to show on the final report and click Export. The reports will be saved to the Download folder of your computer. Please click here to view a larger version of this figure.
Figure 4. Embryo screening and selection using NICS from a patient. A total of six embryos successfully developed to the blastocyst stage, and Day4-Day5 culture medium from each embryo was collected for the NICS assay. (A) and (B) are the NICS results of the two blastocyst embryos showed the same karyotype 45, XN, -18(×1) are both chromosome 18 deletion. (C) showed karyotype 46, XN, +5q (×4), -8(×1, mos) is chromosome 5 duplication and 8 mosaic. (D) showed karyotype 46, XN, -1p (pter→p21.1, ×1) is only the short arm of chromosome 1 pter→p21.1 region deletion, while (E) showed karyotype 46, XN, +1p (pter→p21.2, ×3), -18(q21.32→qter, ×1) is short arm of chromosome 1 pter→p21.2 region duplication and long arm of chromosome 18 q21.32 → qter region (F) showed balanced chromosomal composition. The x axis means 22 autosomes in red and blue, the y axis indicates the copy number of each autosome. The gray dots are the ruler scale of copy number response each bin window and normal karyotype of copy number must be 2. Please click here to view a larger version of this figure.
Table S1. The success rates of DNA detection Option 1 and Option 2. Please click here to download this Table.
Table S2. The concordance between NICS and PGT-A in different options. Please click here to download this Table.
Modifications and troubleshooting
If the NICS results are contaminated with parental genetic materials, make sure all cumulus-corona radiata cells are removed and make sure ICSI is performed for fertilization. Improper medium storage or template preparation processes are avoided, which may degrade DNA. The working space was purified thoroughly with DNase and RNase decontamination reagents. To avoid contamination from other embryos, one embryo was always cultured in a single droplet of medium to avoid cross-contamination starting on day 4. The phenomenon of contamination is minimized when delaying the placement of embryos in the final culture drop30,31,32,33. To minimize maternal contamination, Kuznyetsov34 modified the embryo culture procedures from day 0 to day 4, including careful removal of residual corona cells by pipetting and flushing.
Lane et al.30 shows that when taking the embryo culture medium from day 4 to day 5, the accuracy of euploidy detection is improved, the embryo ploidy consistency is more than 95%, and the consistency of the sex chromosome reaches 100%. Lledo et al.33 found that the coincidence rate between the day 3-day 5 culture medium and TE samples was 74.6% and 92.0% when embryos were cultured from day 4 to day 6.
Our internal data also support this conclusion, as shown in Table S1. Compared with the conventional day 3-day 5 culture method, the granulosa cells were further removed due to one more change in culture medium on day 4 or day 5. We provide internal data (Table S1) showing that our two methods (option 1 and option 2) have good consistency compared with PGT-A, which is better than the sampling method without the thorough removal of CC.
IF-amplified products appeared in the negative control, and external DNA materials may have contaminated the reagent or the working space. The workspace should be cleaned by DNA/RNA removing reagents, nuclease-free materials should be used, and the reagents should be aliquoted after first use.
Differences in the success rates between Option 1 and Option 2 are discussed in Table S1 and Table S2.
Limitations of the NICS assay
There are two main limitations of NICS. 1) Before ICSI, all cumulus cells (usually maternal origin, usually normal chromosome composition) must be removed. If the removal is incomplete, the cumulus cells may release DNA during embryo development and the external DNA is amplified, which may be the cause of false negative detection. 2) It is difficult to remove the sperm attached to the zona pellucida, and the NICS procedure is highly recommended to be carried out with ICSI. Although the regular replacement of cleavage media on day 3 may reduce the possibility of contamination due to cumulus cells and redundant sperm, this contamination must be minimized if NICS is used in clinical IVF. However, a method for detecting NICS in IVF embryos has been developed, including the function of recognizing exogenous DNA, which will be demonstrated in the near future.
This study did not compare the differences between different media since large-scale clinical trials have compared culture media. Eight centers used 4 different culture media, sequential and continuous, and 2 different percentages of albumin supplementation (5% and 10%), and these differences did not have significant effects on the accuracy of embryonic cfDNA results31. These findings support the potential applicability of embryonic cfDNA analysis to every IVF laboratory when working under the specific protocol.
Significance with respect to existing methods
The NICS method avoids embryo biopsy and thus greatly improves the safety of use. Compared with blastocysts, NICS is a simple, time-saving, sensitive and reproducible preimplantation screening technique that is suitable for assisted reproductive populations with a high probability of aneuploidy. Unlike invasive biopsy, which requires considerable and professional knowledge for the blastocyst biopsy procedure, NICS can be applied extensively since its simple collection of spent medium only follows the regular operation of IVF19 and it does not require PGS/PGD qualification in some countries.
Future applications
NICS has the potential for wide applicability for chromosome screening in clinical IVF, not only for ICSI but also for IVF embryos. Although ICSI is highly recommended, methods of removing the sperm attached to the zona pellucida are required to prevent the influence of sperm.
Morphological assessment is a traditional method for embryo evaluation, but in most cases, chromosomally abnormal embryos can appear morphologically similar to chromosomally normal (euploid) embryos. Combining morphological assessment with the NICS assay when transferring ploid embryos with good morphology into the uterus might improve the ongoing pregnancy rates and live birth rate. A randomized clinical trial will be conducted to evaluate the clinical efficacy of single embryo transfer using NICS technology.
Critical steps in the protocol
All cumulus-corona radiata cells must be removed from the oocytes before fertilization. Oocytes were fertilized by intracytoplasmic sperm injection (ICSI). Adding human-derived proteins/supplements to the culture medium was avoided. The culture medium was changed on day 4 and collected on day 5-day 6 when the blastocysts fully expanded. Embryos were cultured in individual droplets of culture medium beginning on day 4. When collecting the culture medium, transfer pipettes between samples were changed to avoid contamination.
The authors have nothing to disclose.
The authors would like to thank Shiping Bo and Shujie Ma for their assistance in NGS data analysis. Funding: this work was supported by the National Key Research and Development Program (Grant No. 2018YFC1003100).
1.5 mL EP tube, 0.2 mL PCR tube | Axygen | MCT-150-C, PCR-02-C | DNase/RNase free, Low Binding PCR tubes and 1.5 mL micro-centrifuge tubes are recommended. |
10 µL, 200 µL, 1000 µL DNase /RNase Free Tips | Axygen | T-300-R-S, T-200-Y-R-S, T-1000-B-R-S | This can be replaced by other brand/For sample transfer |
100 % ethanol | Sinopharm Chemical | 10009218 | This can be replaced by other brand/For DNA library purification |
Barcode Primer1-48 | Yikon Genomics | Reagent in NICSInst library preparation kit | For library amplificaton |
BD Falcon Organ Culture Dish, Sterile | BD Bioscience | 363037 | This can be replaced by other brand/For embryo culture |
BD Falcon Tissue culture Dishes (Easy Grip) , Sterile | BD Bioscience | 353001 | This can be replaced by other brand/For embryo culture |
BD Falcon Tissue culture Dishes, Sterile | BD Bioscience | 353002 | This can be replaced by other brand/For embryo culture |
Cell Lysis Buffer | Yikon Genomics | Reagent in NICSInst library preparation kit | For culture medium pre-treatment |
Cell Lysis Enzyme | Yikon Genomics | Reagent in NICSInst library preparation kit | For culture medium pre-treatment |
ChromGo software | Yikon Genomics | Data analysis | |
CMPure Magbeads | Yikon Genomics | Reagent in NICSInst library preparation kit | For library purification |
Cryotop open systerm | KITAZATO BioPharma | 81110 | This can be replaced by other brand/For embryo vitrification |
Distill water | Yikon Genomics | Reagent in NICSInst library preparation kit | To dissolve DNA |
ES (Vitrification kit) | KITAZATO BioPharma | Reagent inVitrification kit | This can be replaced by other brand/For embryo vitrification |
HOLDNIG | ORIGIO | MPH-MED-35 | This can be replaced by other brand/For ICSI |
Hyaluronidase solution, 80 U/mL | SAGE | ART4007-A | This can be replaced by other brand/Digest oocyte-corona-cumulus complex |
ICSI | ORIGIO | MPH-35-35 | This can be replaced by other brand/For ICSI |
Illumina MiSeq® System | Illumina | SY-410-1001 | For library sequencing |
Incubator | Labotect | Inkubator C16 | This can be replaced by other brand/For embryo culture |
Library buffer | Yikon Genomics | Reagent in NICSInst library preparation kit | For library amplificaton |
Library Enzyme Mix | Yikon Genomics | Reagent in NICSInst library preparation kit | For library amplificaton |
Magnetic Stand | DynaMagTM-2 | 12321D | For library purification |
Microscope | OLYMPUS | 1X71 | This can be replaced by other brand/For embryo observation |
Mini-centrifuge | ESSENSCIEN | ELF6 | For separation |
MT Enzyme Mix | Yikon Genomics | Reagent in NICSInst library preparation kit | For culture medium pre-treatment |
NICSInst library preparation kit | Yikon Genomics | KT1000800324 | Whole genome amplification and library construction |
NICSInst Sample Prep Station | Yikon Genomics | ME1001003 | Amplificate DNA |
Nunc IVF 4-Well Dish | Thermo Scientific | 144444 | This can be replaced by other brand/For embryo washing and blastocyst culture |
Pasteur Pipette | Oirgio | MXL3-IND-135 | This can be replaced by other brand/For embryo tansfer |
Pasteur pipettes | ORIGIO | PP-9-1000 | This can be replaced by other brand/For IVF laboratory |
Pre-Lib Buffer | Yikon Genomics | Reagent in NICSInst library preparation kit | Pre-library preparation |
Pre-Lib Enzyme | Yikon Genomics | Reagent in NICSInst library preparation kit | Pre-library preparation |
Qubit® 3.0 Fluorometer | Thermo Scientific | Q33216 | For library quantification |
Quinn's Advantage Blastocyst Medium | SAGE | ART-1029 | For embryo blastocyst stage culture |
Quinn's Advantage Cleavage Medium | SAGE | ART-1026 | This can be replaced by other brand/For embryo cleavage stage culture |
Quinn's Advantage Fertilization Medium | SAGE | ART-1020 | This can be replaced by other brand/For oocyte and sperm fertilization |
Quinn's Advantage m-HTF Medium with HEPES | SAGE | ART-1023 | This can be replaced by other brand/For embryo clutrure |
Quinn's Advantage SPS Serum protein Substitute Kit | SAGE | ART-3010 | This can be replaced by other brand/To denude the oocyte |
Quinn's Advantage Tissue culture mineral oil | SAGE | ART-4008P | This can be replaced by other brand/To cover the culture medium |
STRIPPER TIPS | ORIGIO | MXL3-IND-135 | This can be replaced by other brand/For denudating granulosa cells |
Vitrification Cryotop Open systerm | KIZTAZATO | 81111 | This can be replaced by other brand/For embryo vitrification |
Vitrification kit | KITAZATO BioPharma | VT101 | This can be replaced by other brand/For embryo vitrification |
Vortexer | Qilinbeier | DNYS8 | Sample mix |
VS (Vitrification kit) | KITAZATO BioPharma | Reagent inVitrification kit | This can be replaced by other brand/For embryo vitrification |
ZILOS-tk Laser System | Hamilton Thorne | CLASS 1 laser | This can be replaced by other brand/For artificial blastocoele collapse |